CN111103880A

CN111103880A - Collaborative navigation operation path planning system and method for unmanned grain combine harvester

Info

Publication number: CN111103880A
Application number: CN201911337126.7A
Authority: CN
Inventors: 崔冰波; 魏新华; 卢泽民; 王爱臣; 吉鑫
Original assignee: Jiangsu University
Current assignee: Jiangsu University
Priority date: 2019-12-23
Filing date: 2019-12-23
Publication date: 2020-05-05
Anticipated expiration: 2039-12-23
Also published as: CN111103880B

Abstract

The invention discloses a collaborative navigation operation path planning system and a collaborative navigation operation path planning method for an unmanned grain combine harvester.A real-time kinematic (RTK-GNSS) collects geographic information of a field, sends the geographic information to a navigation terminal, performs field operation pre-planning, determines grain unloading return point coordinates and grain transporting vehicle positions, and generates a plurality of sections of operation path data, thereby realizing breakpoint cruising path planning; in the operation process of the combine harvester, the RTK-GNSS collects the position and the course of the harvester in real time and sends the position and the course to the navigation terminal, and the navigation terminal sends an expected steering angle to the driving controller for differential steering control according to the transverse error, the course error and the path planning result. In the path planning of unmanned operation in the field of the harvester, the invention combines the breakpoint continuous flight path planning in the grain unloading process, and can effectively reduce the idle running time of the harvester in the field, thereby reducing soil compaction and improving the harvesting operation efficiency and the energy utilization rate.

Description

Collaborative navigation operation path planning system and method for unmanned grain combine harvester

Technical Field

The invention belongs to the field of intelligent agricultural machinery and precision agriculture, and particularly relates to a collaborative navigation operation path planning system and method for an unmanned grain combine harvester.

Background

In recent years, with the popularization and the popularization of a Beidou navigation system, the grain combine harvester based on the automatic navigation system performs operation demonstration in various places successively, and the grain combine harvester without people for operation receives wide attention. However, the unmanned grain harvesting operation is not only influenced by the operation efficiency of the field combine harvester, but also has obvious influence on the comprehensive operation efficiency of the unmanned grain harvesting in the grain unloading link. Currently, most agricultural machine navigation systems do a lot of work around navigation control, work path planning, etc. of combine harvesters. However, the influence of the cooperative operation efficiency of the combine harvester and the grain conveying vehicle in the actual harvesting process on the unmanned harvesting operation in the whole process cannot be ignored.

Disclosure of Invention

In view of the above, the invention provides a collaborative navigation operation path planning system and method for improving the working efficiency and the energy utilization rate of a grain combine harvester and reducing soil compaction in the grain unloading process.

The present invention achieves the above-described object by the following technical means.

A collaborative navigation operation path planning method for an unmanned grain combine harvester is characterized in that a breakpoint cruising path planning of the combine harvester is adopted to realize the collaborative operation path tracking control of the harvester and a grain carrying vehicle;

the specific process of the breakpoint cruising path planning of the combine harvester is as follows: firstly, performing field operation pre-planning, determining grain unloading return point coordinates and grain transporting vehicle positions, and finally generating multi-section operation path data;

the grain unloading return point coordinates are as follows:

wherein: coordinate Z of the point of return flight_kThe serial number of the k-th linear track endpoint in the pre-planned linear path is used; j is a return point index, j is 1,2, …, n; l is_mThe maximum travel of the harvester for single full-width harvesting operation; a-2d is the remaining long edge of the field after the outer-most ring of grains are harvested by the combine harvester;

the determining process of the positions of the grain transporting vehicles comprises the following steps: when the number of the return points is odd, selecting the Y coordinate of the middle return point as the Y axial coordinate of the grain transporting vehicle; when the number of the back-navigation points is even, any one point in the middle two back-navigation points is selectedThe Y coordinate is used as the Y axial coordinate of the grain transporting vehicle; the combine harvester unloads grain at the grain conveying position, and the grain unloading time n is INT (L)_t/L_m) +1, where INT (-) is an integer operator, L_tThe total number of the strokes of field harvesting operation;

the generation process of the multi-section operation path comprises the following steps: sequentially planning a return path from a starting point to a 1 st return point, a jth return point to a j +1 th return point and an nth return point to an operation end point of the return straight path line end point;

the tracking control of the path of the harvester-grain carrier collaborative operation is specifically as follows: the navigation terminal measures the current transverse deviation and course deviation of the harvester in real time, calculates an expected steering angle by combining breakpoint cruising path planning, and sends the expected steering angle to the driving controller for differential steering control.

A collaborative navigation operation path planning system of an unmanned grain combine harvester comprises a navigation terminal, wherein the navigation terminal carries out field operation pre-planning, determines grain unloading return point coordinates and grain transporting vehicle positions, generates multi-section operation path data and realizes breakpoint cruising path planning; the navigation terminal is combined with the real-time position and the real-time course of the harvester to obtain an expected steering angle of the harvester for collaborative navigation tracking control; the system also comprises an RTK-GNSS and a travelling controller, wherein the RTK-GNSS is used for acquiring geographic information of the field and sensing the position and the course of the harvester in real time; the traveling controller receives the desired steering angle and performs differential steering control.

The invention provides a collaborative navigation operation path planning system and a collaborative navigation operation path planning method for an unmanned grain combine harvester, and compared with the prior art, the collaborative navigation operation path planning system has the following beneficial effects:

the method realizes tracking control of the harvester-grain carrier cooperative operation path by planning the breakpoint cruising path of the combine harvester, wherein the planning of the breakpoint cruising path of the combine harvester comprises pre-planning of a field operation path, determination of grain unloading return point coordinates and grain carrier positions and generation of multi-section operation path data; the invention integrates the breakpoint continuous flight path planning of the grain unloading process of the harvester into the path planning of field unmanned operation, thereby improving the intelligent degree of the autonomous operation of the harvester; effectively reduce the empty run distance of harvester in the field, reduced the soil compaction, improved and reaped operating efficiency and energy utilization.

Drawings

FIG. 1 is a flow chart of the breakpoint cruising path planning of the unmanned grain combine harvester of the invention;

FIG. 2 is a schematic view of the position selection of a return point and a grain carrying vehicle of the unmanned grain combine harvester of the invention;

fig. 3 is a flow chart of the tracking control of the cooperative operation path of the unmanned grain combine harvester and the grain carrier.

Detailed Description

The invention will be further described with reference to the following figures and specific examples, but the scope of the invention is not limited thereto.

A collaborative navigation operation path planning system of an unmanned grain combine harvester comprises an RTK-GNSS, a navigation terminal and a traveling controller, wherein the RTK-GNSS collects geographic information of a field, sends the geographic information to the navigation terminal for field operation pre-planning, determines grain unloading return point coordinates and grain transporting vehicle positions, generates multi-section operation path data and realizes breakpoint cruising path planning; when the combine harvester works, the RTK-GNSS senses the position and the course of the combine harvester in real time, sends the position and the course to the navigation terminal, calculates a measurement error (a transverse error and a course error), then calculates an expected steering angle by combining with breakpoint cruising path planning, and the navigation terminal sends the expected steering angle to the driving controller to perform differential steering decision.

A collaborative navigation operation path planning method for an unmanned grain combine harvester is characterized in that a breakpoint cruising path planning of the combine harvester is adopted, so that tracking control of a collaborative operation path of the harvester and a grain transporting vehicle is realized, land compaction and consumed time of a grain unloading link are reduced, and field working efficiency of the combine harvester is improved.

The implementation flow of the breakpoint cruising path planning of the combine harvester is shown in fig. 1, and the specific steps are as follows:

step (1) of generating a linear trajectory end point

Electrifying a navigation terminal and a receiver, acquiring geographic information of a field by using an RTK-GNSS, calculating to obtain size information of the field, pre-planning a linear path of field operation by using the navigation terminal according to the size of the field and the operation width d of a harvester, wherein a pre-planned coordinate system takes the lower left corner of the field as an origin, a vector along the long side direction of the left side of the field is an x-axis, a vector along the short side direction of the field is a y-axis, and all coordinate values of the coordinate system are represented under a Gaussian plane coordinate system; in the pre-planning process, a straight path which is repeatedly reciprocated is adopted to approach the turning track of the harvester, which is the prior art; and storing the end point information of the square-clip-shaped straight-line track generated by the field path preplanning.

Step (2), determining the coordinates of the unloading return point in the pre-planned path, and acquiring the data of the operation path

Calculating the maximum travel L of the harvester for single full-width harvesting operation according to the unit area yield rho, the yield V which can be accommodated in the grain compartment of the harvester and the operation width d (the unit area yield, the yield which can be accommodated in the grain compartment and the operation width are known in the embodiment)_m，L_mV/(ρ × d). The length of the long side of the rectangular field is a, the length of the short side of the rectangular field is b, and the harvester harvests along the long side in the opposite direction of the grain transporting vehicle. After the manual driving combine harvester harvests the grains in the outermost circle, the sizes of the remaining long sides and short sides of the field are respectively as follows: and a-2d and b-2d, the operation line number of the combine harvester along the long side direction is r ═ INT ((b-2d)/d) +1, wherein INT (·) is an integer operator. The operation length of each line is a-2d, and the total stroke number L of the current field harvesting operation_tR (a-2d), the grain unloading times n is INT (L)_t/L_m)+1. The combine harvester is arranged to start to operate from the lower left corner of a field, the field soil compaction in the grain unloading process is reduced, the grain unloading return points are selected as shown in figure 2, namely the return points are arranged at one end, close to a grain carrier, of the field, and the method comprises the following specific steps:

wherein the backspace point index j is 1,2, …, n; z_kFor the kth linear track endpoint serial number in the pre-planned linear path, the return point coordinate is the kth linear track endpoint coordinate, and regeneration is not needed.

And setting a grain unloading return point at a planned line end point of the return-shaped linear path close to one end of the grain unloading vehicle, and sequentially planning the return-shaped path from the starting point of the line end point to the 1 st return point, from the jth return point to the j +1 th return point and from the nth return point to the operation end point to obtain n sections of paths.

Step (3), optimizing the selection of the grain transportation position

As shown in fig. 2, the coordinate of the grain transportation vehicle in the X-axis direction can be set to be 0, and the selection of the position of the grain transportation vehicle is determined by the coordinate of the Y-axis direction. And assuming that the combine harvester runs at a constant speed in the grain unloading process, and selecting the Y-axis coordinate of the grain transporting vehicle based on the shortest total grain unloading path to reduce the time consumed in the grain unloading process. When the number of the return points is odd, selecting the Y coordinate of the middle return point as the Y axial coordinate of the grain transporting vehicle; and when the number of the return points is an even number, selecting the Y coordinate of any one point of the two middle return points as the Y axial coordinate of the grain transport vehicle.

As shown in fig. 3, the tracking control of the path of the harvester-grain vehicle cooperative operation comprises the following specific steps:

after the combine harvester is started, the navigation terminal, the receiver and the driving controller are sequentially powered on, the combine harvester linearly harvests along the long edge of a field, the navigation terminal measures the current transverse deviation and course deviation of the harvester in real time, an expected steering angle is calculated by combining breakpoint continuous path planning and sent to the driving controller to perform differential steering decision, and the calculation of the expected steering angle is the prior art. When a path searching module of the navigation terminal detects that the current straight path is a turning straight path, the traveling controller tracks the straight path back and forth for multiple times, the navigation terminal measures the current transverse deviation and course deviation of the harvester in real time, and calculates an expected steering angle by combining breakpoint continuous path planning and sends the expected steering angle to the traveling controller to perform differential steering decision. When the path searching module confirms that the current line operation is finished, judging whether a grain unloading return point is reached or not by a straight line track end point (line end point), if not, continuing the straight line harvesting operation of the combine harvester along the long edge of the field; if the grain unloading return point is reached, a grain unloading straight line path is planned in real time according to the return point coordinate and the coordinate of the grain transporting vehicle, and the harvester is controlled to drive to the position close to the grain transporting vehicle for grain unloading; and after grain unloading is finished, the navigation terminal updates the path data segment index, judges whether the current path data segment is effective or not, updates road data if the current path data segment is effective, and enters a harvesting operation link along a long edge straight line, otherwise, finishes harvesting operation.

The above description is only of the preferred embodiments of the present invention, and it should be noted that: it will be apparent to those skilled in the art that various modifications and adaptations can be made without departing from the principles of the invention and these are intended to be within the scope of the invention.

Claims

1. A collaborative navigation operation path planning method for an unmanned grain combine harvester is characterized in that a breakpoint continuous flight path planning of the combine harvester is adopted to realize the collaborative operation path tracking control of the harvester and a grain carrying vehicle.

2. The collaborative navigation operation path planning method for the unmanned grain combine harvester according to claim 1, wherein the specific process of the combine harvester breakpoint continuous flight path planning is as follows: firstly, pre-planning field operation, determining the coordinates of grain unloading return points and the positions of grain transporting vehicles, and finally generating multi-section operation path data.

3. The collaborative navigation operation path planning method for the unmanned grain combine harvester according to claim 2, wherein the grain unloading return point coordinates are as follows:

wherein: coordinate Z of the point of return flight_kThe serial number of the k-th linear track endpoint in the pre-planned linear path is used; j is a return point index, j is 1,2, …, n; l is_mThe maximum travel of the harvester for single full-width harvesting operation; and a-2d is the long edge of the field left after the outer-most ring of grains are harvested by the combine harvester.

4. The collaborative navigation operation path planning method for the unmanned grain combine harvester according to claim 3, wherein the determination process of the position of the grain carrier is as follows: when the number of the return points is odd, selecting the Y coordinate of the middle return point as the Y axial coordinate of the grain transporting vehicle; and when the number of the return points is an even number, selecting the Y coordinate of any one point of the two middle return points as the Y axial coordinate of the grain transport vehicle.

5. The collaborative navigation operation path planning method for the unmanned grain combine harvester according to claim 4, wherein the combine harvester unloads grains at a grain transportation position for n-INT (L)_t/L_m) +1, where INT (-) is an integer operator, L_tThe total number of the strokes of the field harvesting operation is calculated.

6. The collaborative navigation operation path planning method for the unmanned grain combine harvester according to claim 2, wherein the multi-segment operation path is generated by the following steps: and sequentially planning the return-shaped path from the starting point to the 1 st return point, the jth return point to the jth +1 st return point and the nth return point to the operation end point of the return-shaped linear path line end point.

7. The collaborative navigation operation path planning method for the unmanned grain combine harvester according to claim 1, wherein the tracking control of the harvester-grain carrier collaborative operation path is specifically: the navigation terminal measures the current transverse deviation and course deviation of the harvester in real time, calculates an expected steering angle by combining breakpoint cruising path planning, and sends the expected steering angle to the driving controller for differential steering control.

8. The collaborative navigation operation path planning system for the unmanned grain combine harvester according to any one of claims 1 to 7, which is characterized by comprising a navigation terminal, wherein the navigation terminal carries out field operation pre-planning, determines grain unloading return point coordinates and grain transporting vehicle positions, generates multi-segment operation path data and realizes breakpoint cruising path planning; and the navigation terminal is combined with the real-time position and the real-time course of the harvester to obtain the expected steering angle of the harvester under the cooperative navigation tracking control.

9. The unmanned grain combine harvester collaborative navigation work path planning system according to claim 8, further comprising an RTK-GNSS and a traveling controller, the RTK-GNSS being configured to collect geographic information of a field and to sense a position and a heading of the harvester in real time; the traveling controller receives the desired steering angle and performs differential steering control.